JPH0980553A - Exposure controlling device for camera - Google Patents

Abstract

PROBLEM TO BE SOLVED: To make a correct stroboscopic shooting and control of shutter speed possible corresponding to an image blurring, and to improve degree of freedom of photographing. SOLUTION: This device is constituted so that an exposure arithmetic part 31 is allowed to output the stroboscopic shooting signal onto the stroboscopic light emitting circuit 22, when the image blurring correction is not possible to be executed by the image blurring correction part 30 and the shutter speed is set slower than the first image blurring decision shutter speed, and to output the stroboscopic shooting signal onto the stroboscopic light emitting circuit 22, when the image blurring correction is possible to be executed by the image blurring correction part 30 and the shutter speed is set slower than the second image blurring decision shutter speed being slower than the first image blurring decision shutter speed.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an exposure control device for a camera having an image blur correction device.

[0002]

2. Description of the Related Art Conventionally, as an exposure control device for a camera, an exposure control device disclosed in Japanese Patent Laid-Open No. 3-24529 has been proposed. In this publication, among the exposure control devices, one that operates the image blur correction means and one that does not operate it are disclosed. Of these, the former exposure control device that does not activate the image blur correction means controls the shutter speed at the time of flash photography not to be slower than a predetermined image blur limit speed, that is, at the image blur limit speed. By doing so, the image blur during so-called slow sync is attempted to be corrected. Here, it is disclosed in the same publication that the image blur limit speed is 1 / focal length (1 /
Focal length).

On the other hand, the latter exposure control device which operates the image blur correction means controls the image blur limit speed to be further lowered to enable effective slow synchronization by the image blur correction. . However, when it is determined that the image blur cannot be corrected by operating the image blur correction means, the shutter speed at the time of shooting is controlled to the maximum speed for strobe synchronization.

[0004]

However, in the above-described exposure control device of Japanese Patent Laid-Open No. 3-24529, the shutter speed is uniformly set to 1 / focal length, or the maximum speed for strobe tuning is set. Are controlled. That is, since control is performed to limit the shutter speed to one value, there is a drawback that the range of brightness of a subject that can be photographed is limited. For this reason, even if the image blur can be corrected, the degree of freedom in photographing is significantly impaired.

SUMMARY OF THE INVENTION An object of the present invention is to provide an exposure control device for a camera, which enables accurate stroboscopic photographing and control of shutter speed in response to image blur, and has a high degree of freedom in photographing.

[0006]

In order to solve the above-mentioned problems, the invention according to claim 1 detects an image blur and drives an image blur correction optical system based on the detection result.
An image blur correction unit that corrects image blur, an image blur correction identification unit that identifies whether or not the image blur correction by the image blur correction unit is possible, and a shutter time determination unit that determines the shutter speed.
In the case where it is determined that the image blur correction is impossible by the strobe image signal generation unit that generates a signal for performing stroboscopic photography and the image blur correction identification unit, the shutter determined by the shutter time determination unit. When the second shutter speed is slower than the first image blur determination shutter speed, the stroboscopic photographing signal is generated by the stroboscopic photographing signal generating unit, and the image blur correction identifying unit determines that the image blur correction is possible. And the shutter time determined by the shutter time determining unit is slower than the second image shake determination shutter time, which is slower than the first image shake determination shutter time, The strobe photographing signal generating section includes a strobe photographing selecting section for generating the strobe photographing signal.

According to a second aspect of the present invention, in the exposure control device for a camera according to the first aspect, when the image blur correction identifying unit determines that image blur correction is impossible, the shutter time determining unit determines The shutter speed determined is the first
When the image blur correction identification unit determines that the image blur correction is possible, the shutter time is determined by the shutter time determination unit. Is provided with a shutter time limiter for limiting the speed so that the speed is not slower than the second image blur limiting shutter time, which is slower than the first image blur limiting shutter time.

[0008]

DETAILED DESCRIPTION OF THE INVENTION Referring to the accompanying drawings,
An embodiment of an exposure control device for a camera according to the present invention will be described in detail.

(First Embodiment) FIG. 1 is a block diagram showing the circuit arrangement of an exposure control apparatus for a camera according to the first embodiment. The exposure control device of FIG.
The main components are the exposure calculation unit 31, the main CPU 14, and the like. The image blur correction unit 30 has a function of correcting image blur at the time of shooting and a function of an identification unit for identifying whether or not image blur correction is possible. The image blur correction unit 30 is mainly composed of a CPU 3, and the CPU 3 includes angular velocity sensors 1 and 2 as an image blur detector and a drive circuit 4.
Etc. are connected.

A motor 5 is connected to the drive circuit 4, and the motor 5 drives the shake correction lens 10 forming a part of the photographing lens so as to be eccentric with respect to the optical axis to correct the image shake. To do. Here, although only one motor 5 is shown, actually two motors 5 are provided to drive the shake correction lens 10 vertically and horizontally. The taking lens includes a first lens 8, a focusing lens 9, a shake correction lens 10, and a diaphragm blade 7.

The angular velocity sensors 1 and 2 respectively detect vertical and horizontal vibrations, and the CPU 3 calculates an image blur amount based on the detection results and the focal length and the photographing distance of the photographing lens. Here, the focal length is stored by the CPU 3, and the shooting distance is calculated from the distance measuring circuit 12 described later by the CPU.
Input to 3. Further, the CPU 3 calculates the drive amount of the blur correction lens 10 based on the calculated image blur amount,
A drive signal for driving the motor 5 by the calculated value is output to the drive circuit 4. The shake correction lens 10 includes a drive circuit 4
Is driven by a predetermined amount. In addition, the CPU 3
An image blur control release switch (SW) 6 is connected,
When the switch 6 is off, image blur correction control is performed,
When it is on, the image blur correction control is not performed.

The main CPU 14 includes a photometry circuit 11, a distance measurement circuit 12, a DX reading circuit 13, a shutter dial 23,
The exposure calculation unit 31 is configured together with the aperture ring 24, and the shutter speed is determined based on the subject brightness input from the photometry circuit 11, the shooting distance input from the distance measurement circuit 12, the film sensitivity input from the DX reading circuit 13, and the like. When, the aperture value is calculated. A shutter control circuit 15 for controlling a shutter (not shown) is connected to the main CPU 14.

A diaphragm control circuit 16 connected to the main CPU 14 controls the opening of the diaphragm blade 7 of the photographing lens, and a focusing control circuit 17 controls a motor 18 based on the distance measurement result of the distance measurement circuit 12 to focus the lens. Drive 9 Further, the main CPU 14 has a display control circuit 1
9, an LCD (not shown) incorporated in the viewfinder displays the shutter speed, aperture value, and the like. Further, the main CPU 14 has a switch (SW).
20, 21, the flash light emission circuit 22 is connected,
Of these, the switch 20 is a half-press switch that is turned on when the release button (not shown) is half-pressed, and the switch 21 is a full-press switch that is turned on when the release button is fully pressed. The strobe light emission circuit 22 is connected to a strobe (not shown), and controls the light emission of the strobe according to the strobe photographing signal of the main CPU 14.

Next, the operation of the exposure control device configured as described above will be described. FIG. 2 is a flowchart (part 1) when the exposure control device of the first embodiment is used, and FIG.
FIG. 4 is a flowchart (No. 2), and FIG. 4 is a program diagram showing combinations of aperture value and shutter speed in the case of programmed automatic exposure. First, in FIG. 2, when a main switch (not shown) is turned on, the sequence starts, and when the release button (SW20) is half-pressed in step S201, the process proceeds to step S202. In step S201, when the image blur control release switch 6 is off, a photographing mode for performing image blur correction control is set, and step S203 is performed.
Starts image blur detection with. On the other hand, when the image blur control release switch 6 (SW6) is on, the photographing mode in which the image blur control is not performed is performed, and the process proceeds to step S204 without performing the image blur control.

In step S204, the film sensitivity is read from the DX code of the film cartridge through the DX contact point, the brightness of the subject is measured in step S205, and the exposure control unit 31 determines the T _V value and the A _V value. . That is, when the exposure mode of the camera is the program exposure, for example, if the lens is 105 mmF2, the measured value from FIG.
The T _V value and the A _V value are determined on the basis of the photometric value according to the program diagram of FIG. And the determined T _V value and A _V value, in step S206, each of the T _V value, the shutter speed corresponding to the A _V values, are converted to the aperture, the display device the value is the display control circuit 19 Is displayed.

In step S207, the distance to the subject is measured, and the focusing lens 9 is driven to adjust the focus on the subject. Next, in step S208, the image blur control release switch 6 (SW6) is turned on again.
When it is determined to be off, and when the image blur control release switch 6 is on, the photographing mode in which the image blur correction control is not performed is performed, and the process proceeds to step S210. In step S210, if the T _V value calculated by the exposure calculation unit 31 is smaller than the value of T _V1 , the process proceeds to step S211, and if T _V1 or more, the process proceeds to S220 in FIG. Here, the value of T _{V1 is} a value corresponding to the first image blur determination shutter speed. That is, since the image blur correction control is not performed, it is considered that the image blur is more likely to occur. Therefore, when the shutter speed corresponding to the T _V value is slower than 1 second of the focal length, the image blur may occur. Judge that there is. As the value of T _V1 , as shown in FIG.
For example, with a lens having a focal length of 105 mm, T _V1 = 6.7.
Becomes

On the other hand, in step S208, when the image blur control release switch 6 is off, the photographing mode for performing the image blur correction control is set. When the image blur detection is started, the process proceeds to step S300, and the image blur correction unit 30 determines whether or not the image blur correction is possible. After the image blur detection by the angular velocity sensors 1 and 2 in FIG. When the detected maximum image blur velocity V _C does not exceed half of the maximum velocity V _D at which image blur correction is possible, it is determined that image blur correction is possible. This judgment loop is repeated until the full-push switch 20 is turned on. The reason why V _C and V _D / 2 are compared is that it is difficult to predict the image blur after full-pressing, and a certain amount of margin is provided.

If it is determined in step S300 that image blur correction is possible, the process proceeds to step S209.
If the T _V value calculated by the exposure calculation unit 31 is smaller than the value of T _V2 , the process proceeds to step S211, and if the T _V value is greater than or equal to T _V2 , the process proceeds to S220. Here, the value of T _V2 is the second
Is a value corresponding to the image blur determination shutter second, and as a result of performing the image blur correction, if the T _V value calculated based on the photometric value is 3 T _V or less than the normal image blur limit value,
It is a value set considering that image blur correction is possible. For example,
As shown in FIG. 3, with a lens having a focal length of 105 mm,
T _V2 = 3.7.

In step S211, the step S2 is executed.
From the comparison results of 09 and 210, it is determined that there is a possibility of image blur if the calculated T _V value is used as it is, and the main CPU 14
And outputs a strobe photographing signal to the strobe light emission circuit 22. Then, it is displayed on the display unit that the flash photography is selected in step S212. As shown in the flowchart (part 2) of FIG. 3, if stroboscopic photography is not possible in step S213, the process proceeds to step S214, and, for example, release lock is performed and the processing ends. If the flash photography is impossible in step S213, (1) In the case of the external flash, the flash is not attached to the camera or charging is not completed. (2) In the case of a built-in flash, it is possible that it has not popped up or charging has not been completed.

As described above, in the steps up to the step S211, it is determined whether or not the strobe is emitted T _V
The value is set to T _V1 corresponding to the first image blur determination shutter time when the image blur correction is not performed, and is set to T _V1 corresponding to the second image blur determination shutter time when the image blur correction is performed.
Change it to something like _V2 . As a result, fine exposure control can be performed, whether or not the strobe is used can be appropriately selected, and the degree of freedom in photographing is further improved.

Further, in step S215, it is determined again whether or not the image blur correction control is performed. If the image blur control release switch 6 is turned on, the photographing mode in which the image blur correction control is not performed is set, and the process proceeds to step S218. . Step S
At 218, the calculated T _V value is compared with T _V3 corresponding to the first image blur limiting shutter speed, and if smaller than T _V3 , S _V is calculated.
219. If T _V3 or more, proceed to S220.

Here, T _V3 corresponding to the first image blur limiting shutter speed is calculated as T _V3 by the exposure calculation unit 31.
_{By V} value to not less than the value of T _V3, is a value set in order to correct the image blur during flash photography. However, to perform the slow synchronization more effectively, T _V3 is a low-speed side value only 2T _V than T _V1, for example, as shown in FIG. 3, the focal length 105mm
Lens, T _V3 = 4.7. In step S219, T _V = T _V3 is set so that T _V does not go to a lower speed side than T _V3 , and the image blur during slow synchronization is corrected in advance.

On the other hand, in step S215, when the image blur control release switch 6 is off, the photographing mode for performing the image blur correction control is set, and the process proceeds to step S301. In step S301, similarly to step S300, it is determined whether the image blur correction unit 30 can perform image blur correction. When it is determined in step S301 that the image blur correction is possible, the process proceeds to step S216. In step S216, if the T _V value is smaller than the value of T _V4 corresponding to the second image blur limiting shutter time, S217.
If T _V4 or more, the process proceeds to S220. Step S
If it is determined in 301 that the image blur correction is impossible, the process proceeds to step S218.

Here, the value of T _V4 corresponding to the second image blur limiting shutter time is set to be smaller than T _V3 corresponding to the first image blur limiting shutter time. This is because in the shooting mode in which the image blur correction control is performed, it is considered that the image blur is unlikely to occur even if the T _V value is smaller than T _V3 because the image stabilizing function works. Further, the shooting performed in the present embodiment is slow sync shooting with image blur correction. For example, in a portrait, the person can receive the strobe light, but the background does not reach the strobe light, which is likely to cause underexposure. In addition, it may be better to set the shutter speed at a low speed in order to balance the entire photograph.

Therefore, the value of T _V4 corresponding to the second image blur limiting shutter second is set to a speed lower than T _V2 by 2 T _V , for example, as shown in FIG.
In the case of the lens, T _V4 = 1.7. When the shutter speed is T _V4 = 1.7, the image blur cannot be completely corrected, but since the background is originally in the out-of-focus range, the photograph can be kept so much that the atmosphere is not spoiled. However, if the speed is slower than this, the background may overlap with a person due to image blur, resulting in a very unsightly photograph. Therefore, in step S217, T _V = T _V4 is set and the shutter speed is T _V4.
I try not to slow it down.

As described above, in steps S215 to S219, the shutter speed limit is changed to T _V3 or T _V4 depending on whether the image blur correction control is performed or not. I have to. As a result, fine-grained control that makes use of the anti-vibration function is possible, and the degree of freedom in shooting during slow synchronization is improved.

Next, if the release button in step S220 is pressed halfway (SW20 on), the process proceeds to step S221. If the release button is fully pressed (SW21 on), the process proceeds to step S222. In step S222,
It is again determined whether or not the image blur control release switch 6 has been operated, and if the switch 6 is on, the shooting mode in which the image blur correction control is not performed is set. Then, in step S223, the image blur correction lens 10 is driven to start the image blur correction control,
It proceeds to step S224. On the other hand, if it is determined in step S222 that the image blur control release switch 6 is turned on, the shooting mode in which the image blur correction control is not performed is set, and step S2 is performed.
Proceed to 24. Then, in step S224, the T _V value,
After shooting according to the aperture value at the shutter speed corresponding to each _AV value, the film is wound in step S225, and the processing is ended.

The following methods are conceivable as methods for determining the values of T _V1 , T _V2 , T _V3 and T _V4 . (1) Assuming that the frequency is frequently used from 28 mm to 105 mm, the value of the above embodiment is fixed. (2) It has a data table corresponding to various lenses and reads the focal length of the attached lens to determine. (3) Read and calculate the focal length of the attached lens.

(Second Embodiment) Next, an exposure control device for a camera according to a second embodiment will be described. In the following embodiments, the same members as those in the first embodiment are the same. A reference numeral is given and a duplicate description is omitted. In the first embodiment, as a method of identifying whether or not image blur correction by the image blur correction unit 30 is possible, the maximum image blur velocity V _C is half the maximum velocity V _D at which image blur compensation is possible.
It is based on whether or not it exceeds. Meanwhile, the second
The second embodiment is different from the first embodiment in that the image blur correction is possible if the error ε of the successively detected image blur does not exceed 30 μm, for example.

FIG. 5 is a flow chart (No. 1) showing the operation of the exposure control device for a camera of the second embodiment, and FIG. 6 is a flow chart (No. 2). As shown in the flowchart (part 1) of FIG. 5, the image blur correction is started between step S202 and step S204. And
When it is determined that the error ε does not exceed 30 μm in steps S208 and S209, and step S302 inserted between steps S215 and S216 of FIG.
Move to 209. On the other hand, if it is determined that the error ε exceeds 30 μm, it is determined that the image blur correction cannot be performed, and the process proceeds to step S210. Press the shutter button fully (S
Repeat until W21 is turned on). According to this, it is possible to determine whether or not the image blur correction is possible from a viewpoint different from that of the first embodiment.

(Third Embodiment) In the third embodiment, the exposure mode is the program automatic exposure only, whereas in the third embodiment, the exposure mode is the program automatic exposure and the aperture priority automatic exposure. The present embodiment is different from the above-described embodiment in the case of a camera having a so-called multi-mode AE of shutter speed priority automatic exposure and manual exposure. Here, FIG. 7 is a flowchart showing an exposure determining method in the case of a camera having a multi-mode AE. FIG. 7 corresponds to step S205 of FIGS. 2 and 6. That is, instead of step S205, the chart of FIG. 7 is replaced by steps S204 and S20 of FIGS.
It may be considered that it is inserted between 6 and 6. FIG. 8 is a program diagram in the case of aperture priority automatic exposure, and FIG. 9 is a program diagram in the case of shutter speed priority automatic exposure.

First, in step S400, it is determined whether or not the program automatic exposure is performed. If it is determined that the program automatic exposure is performed, the process proceeds to step S401 and the T _V value, A
After determining the _V value, the process proceeds to step S206. If it is determined that the program is not the automatic exposure, step S402.
The process proceeds to determine whether the aperture priority auto exposure, if it is determined that the aperture priority auto exposure, the process proceeds to step S403, the T _V value corresponding to the A _V value selected from the photometric value of 8 program Calculate according to the diagram, step S206
Proceed to. If it is determined that the aperture-priority automatic exposure is not set, the process advances to step S404 to determine whether the shutter-second priority automatic exposure is performed.

[0033] In step S404, if it is determined that the time priority auto exposure shutter speed, the A _V value corresponding to T _V value selected proceeds to step S405, calculated from the photometric value in accordance with a program diagram of FIG. 9 , Step S206
Proceed to. If it is determined in step S404 that the shutter-second-priority automatic exposure is not set, step S406.
Proceed to to determine if it is manual exposure.

When it is determined in step S406 that the exposure is manual exposure, the process proceeds to step S407, and the photographer determines the aperture at the shutter speed based on the photometric value, and then proceeds to step S206. If it is determined in step S406 that the mode is not manual, the process returns to step S400 again, and the exposure mode is determined in the same procedure. Then, regardless of the program automatic exposure, aperture-priority automatic exposure, shutter-second-priority automatic exposure, and manual exposure, in steps S206 and thereafter, the T _V values are set to T _V1 , T _V2 , and T _{V1 in} the same procedure as in the first embodiment. T _V3 , T _V4
The control to compare with each value of will be performed.

[0035]

As described above, according to the first aspect of the present invention, it is possible to appropriately select whether to use the strobe, depending on whether or not the image blur correction control is performed. Further, stroboscopic photography can be performed at an appropriate shutter speed while correcting image blur. According to the second aspect of the invention, it is possible to obtain an appropriate exposure depending on the presence or absence of the image blur correction control.

[Brief description of drawings]

FIG. 1 is a block diagram showing a circuit configuration of a first embodiment of a camera exposure control device according to the present invention.

FIG. 2 is a flowchart (part 1) showing the operation of the exposure control device according to the first embodiment.

FIG. 3 is a flowchart (part 2) showing the operation of the exposure control device according to the first embodiment.

FIG. 4 is a program diagram showing combinations of aperture value and shutter speed in the case of program automatic exposure.

FIG. 5 is a flowchart (No. 1) showing the operation of the exposure control device according to the second embodiment.

FIG. 6 is a flowchart (No. 2) showing the operation of the exposure control device according to the second embodiment.

FIG. 7 is a flowchart showing an exposure determination method for a camera having a multi-mode AE.

FIG. 8 is a program diagram in the case of aperture priority automatic exposure.

FIG. 9 is a program diagram in the case of shutter speed priority automatic exposure.

[Explanation of symbols]

 1, 2 Angular velocity sensor 3 CPU 4 Drive circuit 6 Image blur control release switch 10 Blurring correction lens 11 Photometric circuit 12 Distance measuring circuit 13 DX reading circuit 14 Main CPU 15 Shutter control circuit 16 Aperture control circuit 22 Strobe light emitting circuit 30 Image blur correction Section (image blur identification section) 31 Exposure calculation section

Claims (2)

[Claims] 1. An image blur correction unit for correcting image blur by detecting an image blur and driving an image blur correction optical system based on the detection result, and an image blur correction by the image blur correction unit. An image blur correction identification unit that identifies whether or not it is possible, a shutter time determination unit that determines the shutter time, a strobe image signal generation unit that generates a signal for performing stroboscopic photography, and the image blur correction identification unit When it is determined that the image blur correction cannot be performed by the shutter speed determination unit and the shutter speed determined by the shutter speed determination unit is slower than the first image blur determination shutter speed, the strobe photographing signal In the case where it is determined by the image blur correction identifying unit that the image blur correction is possible while the strobe photographing signal is generated in the generating unit, the shutter time determining unit determines the shutter speed. When the shutter speed is slower than the second image blur determination shutter speed, which is slower than the first image blur determination shutter time, the flash photography for generating the strobe photography signal in the strobe photography signal generation unit is performed. An exposure control device for a camera including a selection unit. 2. The exposure control device for a camera according to claim 1, wherein when the image blur correction identification unit determines that image blur correction is impossible, the shutter time is determined by the shutter time determination unit. The shutter speed is determined by the shutter speed determining unit when the image blur correction identifying unit determines that the image blur correction is possible, while limiting the time so that the time is not slower than the first image blur limiting shutter speed. A camera provided with a shutter time limiter that restricts the shutter speed to be lower than the second image shake limiting shutter time, which is slower than the first image shake limiting shutter time. Exposure control device.